Method and system for sealing an annulus enclosing a tubular element

ABSTRACT

The invention provides a method and system for sealing an annulus enclosing a tubular element in a wellbore. The method comprises the steps of: i) introducing a first drilling fluid in the wellbore; ii) drilling an open hole section of the wellbore using a drilling tool suspended at the end of a tool string; iii) pumping a second drilling fluid comprising particles into the wellbore; iv) filtering the particles out of the second drilling fluid near a downhole end of the tubular element; v) extending the tubular element into the open hole section of the wellbore while directing at least part of the filtered particles to an annulus between the tubular element and a wellbore wall. Steps i) to v) may be repeated as often as required.

The present invention relates to a system and method for sealing an annulus enclosing a tubular element. The system and method can be applied for zonal isolation along a liner in a wellbore.

The technology of radially expanding tubular elements finds increasing application in the industry of oil and gas production from subterranean formations. Wellbores are generally provided with one or more casings or liners to provide stability to the wellbore wall, and/or to provide zonal isolation between different earth formation layers. The terms “casing” and “liner” refer to tubular elements for supporting and stabilising the wellbore wall. Typically, a casing extends from surface into the wellbore and a liner extends from a certain depth further into the wellbore. However, in the present context, the terms “casing” and “liner” are used interchangeably and without such intended distinction.

In conventional wellbore construction, several casings are set at different depth intervals, and in a nested arrangement. Herein, each subsequent casing is lowered through the previous casing and therefore has a smaller diameter than the previous casing. As a result, the cross-sectional area of the wellbore that is available for oil and gas production decreases with depth.

To alleviate this drawback, it is possible to radially expand one or more tubular elements at a desired depth in the wellbore, for example to form an expanded casing, expanded liner, or a clad against an existing casing or liner. Also, it has been proposed to radially expand each subsequent casing to substantially the same diameter as the previous casing to form a monodiameter wellbore. It is thus achieved that the available diameter of the wellbore remains substantially constant along (a section of) its depth as opposed to the conventional nested arrangement.

WO-2008/006841 discloses a wellbore system for radially expanding a tubular element in a wellbore. The wall of the tubular element is induced to bend radially outward and in axially reverse direction so as to form an expanded section extending around an unexpanded section of the tubular element. The length of the expanded tubular section is increased by moving, for instance by forcing or pushing, the unexpanded section into the expanded section. Herein the expanded section retains the expanded tubular shape. At its top end, the unexpanded section can, for instance, be extended by adding pipe sections or by unreeling, folding and welding a sheet of material into a tubular shape.

When lining a wellbore using the system of WO-2008/006841, the annulus between the expanded tubular element and the wellbore wall will be relatively small in comparison to conventional casing systems. The expanded pipe section will be in close proximity to or even engage the wellbore wall. Consequently it is impossible to perform a conventional cementing job, which is typically used to establish zonal isolation when using conventional casings in a nested arrangement.

In a conventional cementing job, when cementing a liner a slurry for forming cement may be pumped downhole via the drill string, via the downhole end of the drill string and uphole via the annulus between the casing or liner and the wellbore wall. Otherwise, the cement slurry may be pumped through the inner fluid passage of the casing while being contained between two cement plugs.

Due to the relatively small annulus between the inverted pipe and the well bore wall when using the system of WO-2008/006841, it would require a relatively high pressure difference to pump the cement slurry into the annulus. Also, pumping cement slurry into the small annulus may result in a non-uniform fill off the annulus. In addition, the everted pipe may engage the wellbore wall along at least a part of its length, so that the annulus may lack a continuous flow path from its downhole end to surface. When the inverted tubular has engaged the wellbore wall along a certain length and thereby established zonal isolation, circulating fluid or cement slurry through the annulus will be impossible.

The present invention aims to overcome the problem described above.

The present invention therefore provides a method for sealing an annulus enclosing a tubular element in a wellbore, wherein the tubular element is an expandable tubular element enclosing a tool string, wherein a downhole end portion of a wall of the expandable tubular element is bent radially outward and in axially reverse direction defining an expanded tubular section extending around an unexpanded tubular section, the method comprising the steps of:

i) introducing a first drilling fluid in the wellbore;

ii) drilling an open hole section of the wellbore using a drilling tool suspended at the end of the tool string;

iii) pumping a second drilling fluid comprising particles into the wellbore;

iv) filtering the particles out of the second drilling fluid near a downhole end of the tubular element;

v) extending the tubular element into the open hole section of the wellbore by pushing the unexpanded section into the expanded tubular section, while directing at least part of the filtered particles to an annulus between the expanded tubular section and a wellbore wall.

The method of the present invention obviates the need to circulate cement through the annulus. The method also enables the sealing an the annulus in combination with a system for expanding a liner in a wellbore by everting said liner. Also, the method of the invention is suitable to isolate the annular space enclosing a conventional casing, for instance in case said annular space between said casing and an enclosure would be too small to allow the pumping of a cement slurry or in case the pressure required to pump said cement slurry would exceed the maximum output pressure of available pumping equipment.

In an embodiment, steps i) to v) are repeated as often as required. For instance, as often as required to provide sufficient zonal isolation in the annulus. Also, the entire annulus may be filled with particulate matter.

In another embodiment, the step of filtering the particles comprises moving a drill string provided with a filter member uphole, until said filter member engages a downhole end of the tubular member.

The step of introducing a first drilling fluid in the wellbore may comprise moving the drill string provided with the filter member downhole until the filter member is disengaged from the downhole end of the tubular member.

Alternatively, the particles may be at least partially ferromagnetic, wherein the step of filtering the particles comprises arranging a magnet at the downhole end of the tubular member to attract at least a part of the particles.

By moving the unexpanded tubular section downward relative to the expanded tubular section, the tubular element is effectively turned inside out. The tubular element is progressively expanded without an expander that is pushed, pulled or pumped through the tubular element. The expanded tubular section can form a casing or liner in the wellbore. The expanded tubular liner may have a collapse resistance which is adequate to stabilize or support the wellbore wall.

It is preferred that the wall of the tubular element includes a material that is plastically deformed during expansion. The expanded tubular section will retain an expanded shape due to the plastic deformation, i.e. permanent deformation, of the wall of the expandable tubular element. There is no need to apply an external force or pressure to maintain the expanded tubular section in its expanded form. If, for example, the expanded tubular section engages the wellbore wall, no additional radial force or pressure needs to be exerted to keep the expanded tubular section against the wellbore wall.

The wall of the tubular element may comprise a metal such as steel or any other ductile material capable of being plastically deformed by eversion of the tubular element. The expanded tubular section preferably has adequate collapse resistance to support or stabilize the wellbore wall. Depending on the respective formation, the collapse resistance of the expanded tubular section may exceed, for example, 100 bar to 150 bar. The collapse resistance may be in the range of for instance 200 bar to about 1600 bar or more, for instance about 400 bar to 800 bar or more.

Suitably the bending zone is induced to move in axial direction relative to the remaining tubular section by inducing the remaining tubular section to move in axial direction relative to the expanded tubular section. For example, the expanded tubular section is axially fixed at some location, while the unexpanded tubular section is moved in axial direction through the expanded tubular section to induce said bending of the wall.

In order to induce said movement of the remaining tubular section, the remaining tubular section is subjected to an axially compressive force acting to induces said movement. The axially compressive force preferably results at least partly from the weight of the remaining tubular section. A pushing device may supplement the weight of the unexpanded tubular section by applying an additional external force to the remaining tubular section to induce said movement. The additional force applied by the pushing device may be upward or downward. For instance, as the length and hence the weight of the unexpanded tubular section increases, an upward force may need to be applied to the unexpanded tubular section to maintain the total force applied to the unexpanded section within a predetermined range. Maintaining the total force within said range will prevent uncontrolled bending or buckling of the bending zone.

If the bending zone is located at a lower end of the tubular element, whereby the remaining tubular section is axially shortened at a lower end thereof due to said movement of the bending zone, it is preferred that the remaining tubular section is axially extended at an upper end thereof in correspondence with said axial shortening at the lower end thereof. The remaining tubular section gradually shortens at its downhole end due to continued reverse bending of the wall. Therefore, by extending the remaining tubular section at its upper end to compensate for shortening at its lower end, the process of reverse bending the wall can be continued until a desired length of the expanded tubular section is reached. The remaining tubular section can be extended at its upper end, for example, by connecting a tubular portion to the upper end in any suitable manner such as by welding. Alternatively, the remaining tubular section can be provided as a coiled tubing which is unreeled from a reel and subsequently inserted into the wellbore.

Optionally the bending zone can be heated to promote bending of the tubular wall.

The invention will be described hereinafter in more detail and by way of example with reference to the accompanying drawings in which:

FIG. 1 shows a vertical cross section of a lower portion of a system for radially expanding a tubular element;

FIG. 2 shows a vertical cross section of an example of an upper portion of the system of FIG. 1;

FIG. 3 shows a vertical cross section of another example of an upper portion of the system of FIG. 1;

FIG. 4 shows a vertical cross section of a wellbore, indicating a first step in a method according to the invention;

FIG. 5 shows a vertical cross section of a wellbore, indicating a second step in a method according to the invention;

FIG. 6 shows a vertical cross section of a wellbore, indicating a third step in a method according to the invention;

FIG. 7 shows a vertical cross section of a wellbore, indicating a fourth step in a method according to the invention;

FIG. 8 shows a vertical cross section of an embodiment of a system for use in the method of the invention;

FIG. 9 shows a vertical cross section of another embodiment of a system for use in the method of the invention;

FIG. 10 shows a vertical cross section of yet another embodiment of a system for use in the method of the invention;

FIG. 11 shows a vertical cross section of an embodiment of a filter for use in the method of the invention, in a first position; and

FIG. 12 shows a vertical cross section of the filter of FIG. 11, in another position.

In the drawings and the description, like reference numerals relate to like components.

FIG. 1 shows a wellbore 1 formed in an earth formation 2. A radially expandable tubular element 4, for instance an expandable steel liner, extends from surface 6 down into the wellbore 1. The tubular element 4 comprises an unexpanded tubular section 8 and a radially expanded tubular section 10. The unexpanded section 8 extends within the expanded section 10. Preferably, an outer diameter of the expanded tubular section 10 is substantially equal to the diameter of the wellbore 1.

Although the wellbore shown in FIG. 1 extends vertically into the formation 2, the present invention is equally suitable for any other wellbore. For instance, the wellbore 1 may extend at least partially in horizontal direction. Herein below, upper end of the wellbore refers to the end at surface 6, and lower end refers to the end down hole.

At its lower end, the wall of the unexpanded section 8 bends radially outward and in axially reverse (in FIG. 1 the upward) direction so as to form a curved downhole section 12, defining a bending zone 14 of the tubular element 4. The curved section 12 is U-shaped in cross-section and interconnects the unexpanded section 8 and the expanded section 10.

A drill string 20 may extend from surface through the unexpanded liner section 8 to the lower end of the wellbore 1. The downhole end of the drill string 20 is provided with a drill bit 22. The drill bit comprises, for instance, a pilot bit 24 having an outer diameter which is slightly smaller than the internal diameter of the unexpanded liner section 8, and a reamer section 26 having an outer diameter adapted to drill the wellbore 1 to its nominal diameter. The reamer section 26 may be radially retractable to a smaller outer diameter, allowing it to pass through the unexpanded liner section 8, so that the drill bit 22 can be retrieved through the unexpanded liner section 8 to surface. The drill string 20 may comprise multiple drill pipe sections 28. The pipe sections 28 may be mutually connected at respective ends by male and female threaded connections 30. An annular space 32 between the drill string 20 and the unexpanded tubular section 8 is referred to as the drilling annulus 32.

The connections 30 are not shown in detail, but comprise for instance threaded, pin and box type connections. The connections 30 may comprise joints fabricated with male threads on each end, wherein short-length coupling members (not shown) with female threads are used to join the individual joints of drill string together, or joints with male threads on one end and female threads on the other. Said threaded connections may comprise connections which are standardized by the American Petroleum Institute (API).

FIG. 1 also shows a rig floor 40, which is elevated with respect to the surface 6 and encloses an upper end of the drill string 20 and of the unexpanded tubular section 8. The rig floor 40 is part of a drilling rig, which is however not shown in its entirety. A pipe pusher 42, which is for instance arranged below the rig floor, encloses the unexpanded section 8. The pipe pusher is for instance supported by base frame 43. The base frame 43 provides stability, and may for instance be connected to the drilling rig or be supported at surface 6. The pipe pusher may comprise one or more motors 46, which are arranged on the base frame, and one or more conveyer belts 48 which can be driven by the respective motors. Each conveyer belt 48 engages the outside of the unexpanded section 8. The conveyer belts 48 can exert force to said unexpanded section 8 to force the unexpanded section to move into the expanded section 10. Other embodiments of the pipe pusher 42 are conceivable, which will be able to exert downward or upward force to the unexpanded section.

A sealing device 50 can be connected to the upper end of the expanded liner section 10 to seal the unexpanded liner section 8 relative to the expanded liner section 10. Herein, the sealing device 50 enables the unexpanded liner section 8 to slide in axial direction relative to the sealing device 50. The sealing device comprises a conduit 52 which is connected to a pump (not shown) for pumping fluid into or out of a blind annulus 44, i.e. the annular space between the unexpanded liner section 8 and the expanded liner section 10. The annular space 44 is referred to as blind annulus as it is closed at the downhole end by the bending zone 14. The sealing device includes one, two or more annular seals 56, 58. The seals 56, 58 engage the outside of the unexpanded section 8 and prevent said fluid to exit the blind annulus. Preferably, the sealing device 50 comprises at least two seals 56, 58 to provide at least one additional seal to improve safety and reliability in case the first seal may fail.

The sealing device 50 can be regarded as a blind annulus blow out preventer (BABOP). Therefore, the seals 56, 58, the connection of the device 50 to the upper end of expanded section 10, and one or more valves (not shown) for closing conduit 52 will all be designed to at least withstand fluid pressures that may arise in a well control situation. Depending on specifics of the formation, the sealing device 50 is for instance designed to withstand pressures that may be expected in case of a blowout, for instance in the range of 200 bar to 1600 bar, for instance about 400 bar to 800 bar or more. Such pressures may for instance arise in the blind annulus 44 in case of a failure, for instance due to rupture, of the expandable tubular 4 in combination with a well control situation.

The expanded liner section 10 is axially fixed, by any suitable fixation means, to prevent axial movement. The expanded liner section 10 may be fixated at its upper end at surface. For instance, said upper end of the expanded section may be connected to a ring or flange 59, for instance by welding and/or screwing. Said ring can be attached to or incorporated in any suitable structure at surface, such as the sealing device 50. The inner diameter of said ring may be larger than the outer diameter of the expanded section. Optionally, the expanded section 10 may be fixed to the wellbore wall 224, for instance by virtue of frictional forces between the expanded liner section 10 and the wellbore wall 224 as a result of the expansion process. Alternatively, or in addition, the expanded liner section 10 can be anchored, for instance to the wellbore wall, by any suitable anchoring means.

At the interface indicated by the line II-II, the lower portion of the system shown in FIG. 1 can be connected to an upper portion as for instance shown in FIGS. 2 and 3.

FIG. 2 shows a top drive 60 connected to an upper end connection part 62, which is rotatable with respect to the top drive. Preferably, the upper end connection part comprises a flush pipe, having a smooth outer surface. A connection part end 64, which is remote from the top drive, is provided with a threaded connection 30 as described above. The threaded end 64 is connected to an additional drill string section 66. Typically, the additional drill string section 66 will be substantially equal to the drill string sections 28, shown in FIG. 1. At the interface indicated by line I-I, the additional drill pipe section 66 can be connected to the upper end of the drill string 20 shown in FIG. 1.

A drilling annulus sealing device 70 may cover the top end of the drilling annulus 32. The sealing device 70 comprises a housing 72, which encloses the connection part 62 and provides an internal space 74. At the top end, near the top drive 60, the housing may comprise one, two or more seals 76, 78, which engage the outside of the pipe 62. Preferably, the seals 76, 78 enable the housing to slide along the pipe 62. At the opposite end, the housing may comprise one, two or more seals 80, 82 which engage the outside of an additional expandable pipe section 84. In addition to the seals, the housing may comprise grippers 106, which may engage the outside and/or the inside of the pipe section 84. An activation line 88 is connected to the housing for activating or releasing the seals 80, 82 and/or the grippers 106. A fluid conduit 90 is connected to the internal space 74 for supply or drainage of (drilling) fluid to or from the annular space 32.

The sealing device 70 may comprise an extending part or stinger 100. The stinger extends into the inside of the additional expandable pipe section 84. The stinger may comprise seals 102, 104 and/or grippers 106 to engage the upper end of the pipe section 84. The stinger may also comprise seals 108 to engage a lower end of the pipe section 84, and seals 110 to engage the inside of the upper end of the unexpanded tubular section 8 (shown in FIG. 1). A backing gas tool 198 may be integrated in the stinger between the seals 108, 110. The backing gas tool covers the inner interface between the additional expandable pipe section 84 and the unexpanded tubular section 8.

The stinger may be at least slightly longer than the pipe section 84 so that the stinger may extend into the unexpanded section 8, which will enable the stinger to function as an alignment tool for aligning the pipe section 84 and the unexpanded section 8.

In practice, the length of the pipe section 84 may be in the range of about 5-20 metres, for instance about 10 metres. The stinger will for instance be about 2% to 10% longer, for instance 5% longer than the pipe section 84. An annular space 112 is provided between the stinger and the pipe 62 to provide a fluid connection from the annulus 32 to the space 74 and the conduit 90.

The sealing device 70 may be referred to as drilling annulus blow out preventer (DABOP) 70. The seals 76-82, the grippers 106, and one or more valves (not shown) for closing conduits 88 and 90 will all be designed to at least withstand fluid pressures that may arise in a well control situation. Depending on specifics of the formation and the expected maximum pore pressures, the DABOP 70 is for instance designed to withstand pressures in the range of about 200 bar to 800 bar or more, for instance about 400 bar.

The DABOP may comprise any number of seals. The DABOP 70 may comprise one seal 76 and one seal 80, or a plurality of seals. In a practical embodiment, two seals 76, 78 to seal with respect to the pipe 62 and two seals to seal with respect to the tubular section 84 will provide a balance between for instance fail-safety and reliability on one hand and costs on the other hand. For instance, the double barrier provided by the inner seals 102, 104, engaging the inside of the expandable pipe 84, and the outer seals 80, 82, engaging the outside of the expandable pipe 84, improves the reliability and leak-tightness of the sealing device 70.

FIG. 3 shows an upper portion of the system of FIG. 1. The unexpanded liner section 8 is at its upper end formed from a (metal) sheet 130 wound on a reel 132. The metal sheet 130 has opposite edges 133, 134. After unreeling from the reel 132, the metal sheet 130 is bent into a tubular shape and the edges 133, 134 are interconnected, for instance by welding, to form the unexpanded tubular section 8. Consequently, the expandable tubular element 4 may comprise a longitudinal weld 135.

A fluid conduit 136 extends from the interior of the unexpanded tubular section 8, to above the upper end of the unexpanded tubular section 8. The fluid conduit 136 may at its lower end be connected to, or integrally formed with, a tube 138 located in the unexpanded tubular section 8. A first annular seal 140 seals the tube 138 relative to the unexpanded liner section 8, and a second annular seal 142 seals the tube 138 relative to the drill string 20. The fluid conduit 136 is in fluid communication with the interior space of the tube 138 via an opening 144 provided in the wall of the tube 138. Furthermore the tube 138 is provided with gripper means 146 allowing upward sliding, and preventing downward sliding, of the tube 138 relative to the unexpanded liner section 8. The first annular seal 140 allows upward sliding of the tube 138 relative to the unexpanded liner section 8.

The upper portion shown in FIG. 3 can be combined with a lower portion shown in FIG. 1, wherein the unexpanded tubular section 8 is however continuously formed around the drill string 20. Herein, some of the features shown in FIG. 1 are omitted in FIG. 3 to improve the clarity of the latter figure, such as the sealing device 50, the pipe pusher 42 and drilling floor 40.

The method of sealing the annulus enclosing a liner according to the present invention is described herein below in subsequent steps. The sequence of steps may be performed repeatedly to provide a lined and zonally isolated wellbore.

FIG. 4 shows the wellbore 1 provided in earth formation 2. The wellbore is provided with expandable liner 4. The liner comprises unexpanded section 8 and radially expanded section 10. The expanded section 10 may be clad against the wellbore wall 224, or may leave a relatively small annular space 202 between the expanded section 10 and the wellbore wall 224. The drill string 20 extends through the liner 4 and is provided with a drill bit 22 at its downhole end 200, near the bottom of the wellbore 1. The drill bit may comprise a pilot bit 24 and a reamer section 26.

An annulus 202 between the expanded section 10 and the wellbore wall 224 is provided with a layer a sealing material 204, providing a previously sealed section 206 of the wellbore.

In a first step, starting from the previously sealed section 206, drilling of the borehole 1 is continued without further inverting the liner pipe 4, creating an open hole section 208. After reaming using the reamer 26, said open hole section 208 may have a diameter which is slightly larger than the outer diameter of the expanded liner section 10. Slightly larger herein for instance indicates a range of about 0.1 to 20 mm, typically a few millimetres or less. During drilling, the wellbore 1 including the open hole section 208 is filled with drilling fluid 210.

In a second step (FIG. 5), a filter member 212 is arranged at the bending zone 14 of the liner 4. The filter member may have any shape suitable to stay in a predetermined position at or near the bending zone 14. Subsequently, particles 220 are included in the drilling fluid 210 and pumped downhole through the drill bit 22 and are subsequently caught by the filter member 212.

As shown in FIG. 5, the filter member may have a cylindrical shaped body 214 fitting within the inner diameter of the unexpanded liner section 8. The cylindrical body is provided with a radially extending flange member 216 to engage the bending zone 14 and to retain the filter member in the proper location. The flange member 216 may be retractable to enable the introduction of the filter member through the inside passage of the unexpanded liner section 8. An outer diameter of the flange member 216 may be about equal to or smaller than the outer diameter of the expanded liner section 10, to allow the particles to pass the flange member and to reach the annulus 202.

The filter member is for instance provided with openings or fluid passages that substantially allow the passage of drilling fluid but which are smaller than the average size of the particles 220. For instance, the filter member may include openings provided with a metal mesh having openings which are smaller than said size of the particles.

In a third step (FIG. 6), the tubular member 4 is everted further. As a result the bending zone will engage the filter member 212 and move said filter member downhole. During the eversion of the liner 4, drilling fluid 210 including said particulate matter 220 is pumped downhole via the drill string 20. The filter 212 will trap the particles 220 in the return flow of drilling fluid. Said trapped particles 220 will pass the filter member on the outside and enter the annulus 202. Thus, the particles 220 fill the annulus, close off said annulus and provide zonal isolation in the annulus of the newly lined section of the wellbore.

A thin layer 222 of particles in the annulus is caught between the expanded tubular section 10 and the wellbore wall 224. Said thin layer may have a thickness comparable to the thickness of the annular space 202, for instance in the range of about 10 mm or less.

In a fourth step (FIG. 7), when the tubular element 4 has been everted and extends a predetermined distance along the wellbore section 208, the filter member 212 is removed from the wellbore and any excess particles 212, which are not caught in the annulus 202, are flushed out by pumping suitable fluid (without particles) down the wellbore via the drill string 20.

After completing the fourth step, the process can be repeated starting at the first step (FIG. 4).

Please note that the method described above is also suitable to provide a layer of particles or other particulate matter in the annular space surrounding a regular, non-everting liner pipe. If said liner pipe is not everted however, the pipe can only be introduced into the wellbore up to a threshold length, as the friction between the pipe and the particles will eventually prevent the pipe from moving further.

The filter 212 shown in FIG. 11 allows a continuous process. Herein, drilling the wellbore and everting the pipe 4 can be performed continuously. The particles 220 are pumped down in batches or continuously. The total amount of particles in the drilling fluid is at least sufficient, to provide a sufficient amount of particles below the filter 212 to be trapped in the annulus between the expanded pipe section 10 and the wellbore wall. The particles get trapped between the outside of the cylindrical filter section and the wellbore wall 224. The downhole end of the cylindrical filter section is provided with a flexible flap 252. Said flap preferably has a circular shape. Alternatively, the flap may be comprised of a number of flaps, together constituting said circular shape. The flap 252 has a closed position (FIG. 11), wherein the flap 252 at least partially closes the gap between the cylindrical filter section 252 and the drill string 20. When the fluid pressure of the fluid below the flap exceeds a predetermined threshold pressure, the flap 252 may open to an open position (FIG. 12), wherein at least a part of the gap between the cylindrical filter section 252 and the drill string 20 is open to provide a fluid passage.

When the flap 252 on the inside of the filter section 252 is in the closed position (FIG. 11), the flap at least partially seals the annulus between the drill string and the filter section. This allows pressure build up in the annulus between the outside of the filter section 250 and the wellbore wall 224. Said pressure compacts the particles, which are trapped between the filter section 250 and the wellbore wall 224, already a bit. Due to the eversion of the tubular element 4, the particles get trapped between the expanded pipe section 10 and the wellbore wall 224, compacting said particles even more.

When the pressure difference across the flap 252 exceeds the threshold pressure, for instance due to too much drilling fluid flow from the bit, the flap(s) open (FIG. 12). The opening flap allows a balance between circulation of drilling fluid (including the delivery of particles to the annulus, and removing of the cuttings from the borehole) and compacting of the particles by the filter 212. It also prevents the particles from blocking the drilling annulus between the drill string 20 and the unexpanded pipe section 8.

The flap 252 may move between the closed and open position in various ways. The transition from closed to opened may for instance be gradually or instantly. Gradually herein means that the flexible flap will open gradually, for instance by bending. The latter allows stepless opening of the annulus and allows said annulus to be opened any predetermined percentage between 0 and 100%, depending on the pressure differential. Thus, the flap enables an intermediate position wherein the annulus is partially closed and partially open, for instance a half open position. The flaps may for instance be made of a flexible rubber having a suitable bending stiffness. In addition, the geometry and shape of the flap can be designed to cause a predetermined bending related to the pressure differential. Instant opening implies the flaps moving from the closed to the opened position in a stepped way, i.e. either open or closed. The latter may be roughly compared to the mechanism of a light switch.

The length of the layer 222 is for instance in the range of about 1 km or less, for instance about 500 meters down to a few metres. The zonal isolation process of the present invention is semi-continuous, and tripping of the drill string in and out of the wellbore is obviated.

The present invention enables to trap particles 220 between the expanded liner section 10 and the wellbore wall, while limiting the sealing capabilities of said particles to the annulus 202 between the expanded liner section 10 and the wellbore wall. I.e. the particles are prevented from clogging other parts of the wellbore.

When the particles 220 are pumped downhole through the drill string 20, they need to get caught in the annulus, at the bending zone 14. Practical embodiments for this purpose include:

1) The filter member 212 is buoyant in the applied drilling fluid (FIG. 8). Said filter member can freely move along the drill string 20. The bending zone 14 prevents upward (uphole) movement of the filter member, thus maintaining the filter in the appropriate position.

During drilling of the wellbore, the filter member 212 is moved downhole to allow drill cuttings to pass the filter. A radially extending ridge 230 may engage the filter member 212 and force it downhole together with the drill pipe, away from the bending zone 14, when the drill string 20 is moved downhole while drilling.

2) A filter member 212 (FIG. 9) is attached to the drill pipe 20. Said filter member may typically have a cylindrical body which is longer than cylindrical body of other embodiments of the filter member. The filter member may lack a flange member. The exact location of the drill pipe 20 with respect to the bending zone 14 is not that critical, since the filter is relatively long.

3) A (strong) magnet 240 may be arranged in the annulus 44 between the expanded and unexpanded liner sections (FIG. 10). The particles are selected to be at least partially ferro-magnetic. While pumping particles, they are attracted by the magnet and caught at the bending zone 14. At the inside of the unexpanded liner section 8, the velocity of (drilling) fluid will be relatively high, while below or at the bending zone 14 the fluid flow will stagnate. Consequently, the ferro-magnetic particles will attach to the bending zone 14 of the liner 14, and not clog up the annulus between the unexpanded liner section 8 and the drill pipe 20. While everting the liner 4, said particles attached to the bending zone will be transported into the annulus 202 and get trapped in said annulus 202.

The particles may for instance be transported by fluid flow. Alternatively the particles may be buoyant in the particular drilling fluid which is used. As a result, a relatively low density of the particles is required.

The particles may include one or more of:

-   -   Swelling rubbers, elastomers or clay. Swelling herein may         indicate that the material of which the particles are made will         swell when contacted with a certain fluid, such as water or         hydrocarbons. If the particles 220 are swelling, the zonal         isolation of the annulus 202 will improve over time. The amount         of swell of the particles during placement is preferably kept to         a minimum, for instance 0% to 10% swell in volume or diameter.         The swelling of the particles when placed is preferable larger         than the swell during placement, for instance 100-200% or more         swell in volume or diameter, for instance up to 1000% swell in         volume. For suitable materials, reference is made to for         instance U.S. Pat. No. 7,578,347.     -   Non swelling rubbers, elastomers or cuttings. The particles are         crushed during the expansion of the pipe 4 and a tightly packed         layer 222 is formed.     -   Particles including an activating ingredient that will help to         set the remaining fluid left behind in the annulus. The         activating ingredient may include, for instance, one or more of         a Super Absorbent Polymer or a chemically reacting substance.         The activating ingredient(s) may be released by, for instance:         Bleeding from the particle during a predetermined bleeding time,         or dissolvable capsules or capsules that break when being         crushed during the expansion of the pipe.

The density of naturally buoyant particles is lower than the density of the drilling fluid. Typically, drilling fluid has a density of the same order as the density of water, i.e. around 1 Specific Gravity (SG). For instance, the drilling fluid may have a density in the range from 0.8 to 5 SG, or for instance 1 to 2.5 SG. The choice of drilling fluid may depend on multiple factors, including the properties of the formation. The buoyant particles have a lower density than that of the drilling fluid, preferably a difference in density of 0.1 SG or more. The density of the buoyant particles may be in the range of 0.7 to 2.4 SG.

The particles may have a non-uniform size. The particle size distribution may depend, for instance, on the size of the annulus 202 or the permeability of the formation. The largest particles may be as large, or slightly larger than, the annular space 202 between the expanded pipe section 10 and the wellbore wall 224. Said annular space, for instances in the range of 0.1 to 20 mm, or for instance 3 to 6 mm. The size of the smallest particles may depend on the formation and the chosen drilling fluid. The smallest particles may fill the voids between the larger particles, thereby creating a dense packing. The smallest particles may be in the size of nano-particles or larger. Preferably, the permeability of the packing of particles in the annulus is lower than the permeability of the formation at the respective location.

In another embodiment, as an alternative means to have sealing particles available in front of the point of pipe inversion (i.e. the bending zone 14), particles which are lighter than mud particles could be used. Said particles would, on account of their buoyancy, have the tendency to travel upwards. By arranging an impermeable pipe over the inversion zone with an outer diameter smaller than the hole, and which has a (moving) seal with the original (un-inverted) SOCCS pipe, an annular space is created below the point of inversion. The lighter than mud particles would have the natural tendency to accumulate in said space and, thus, act as the sealing material required around the inverted pipe. When inventing the pipe and extending the expanded section, at least a part of the particles trapped between the impermeable pipe and the wellbore wall will be transported to the annulus between the expanded tubular section 10 and the wellbore wall. Once the particles are in the latter annulus, the particles may provide the zonal isolation as described above with respect to other embodiments.

In a practical embodiment, the diameter and/or wall thickness of the liner 4 can be selected such that the expanded liner section 10 is pressed against the wellbore wall 224 during the expansion process. The expanded liner 10 may thus seal against the wellbore wall and/or stabilize the wellbore wall. Also, the expanded liner may squeeze the particles 220 between its outer surface and the wellbore wall.

The wall thickness of the liner 4 may be equal to or thicker than about 2 mm (0.08 inch). The wall of the liner 4 may have a thickness of, for instance, more than 2.5 mm, for instance about 3 to 30 mm or about 3.2 to 10 mm. The outer diameter of the unexpanded section may be about 50 mm (2 inch) or more, for instance in the range of about 50 to 400 mm (16 inch). The expanded section may have any outer diameter suitable for or commonly used for hydrocarbon wellbores. The wall of the liner may comprise a relatively strong material, such as a metal or preferably steel, or may be made of solid metal or solid steel. Thus, the liner 4 can be designed to have adequate collapse strength to support a wellbore wall and/or to withstand internal or external pressures encountered when drilling for hydrocarbon reservoirs.

The length and hence the weight of the unexpanded liner section 8 will gradually increase during extension of the wellbore. Hence, the downward force exerted by the pushing device 42 can be gradually decreased in correspondence with the increasing weight of unexpanded liner section 8. As said weight increases, the downward force eventually may need to be replaced by an upward force to maintain the total force within a predetermined range. This may prevent buckling of liner section 8.

During drilling, the unexpanded liner section 8 proceeds into the wellbore while the drill string 20 also gradually proceeds into the wellbore 1. The unexpanded liner section 8 may be pushed into the wellbore at about twice the speed as the drill string 20, so that the bending zone 14 remains at a relatively short distance above the drill bit 22. Herein, said short distance indicates the length L1 of the open hole section 208 (see FIGS. 1 and 4), i.e. the unlined section, of the wellbore 1. The method of the present invention enables an open hole section having a length L1 smaller than, for instance, about 100 or smaller than 50 metres at all times while drilling the wellbore.

The unexpanded liner section 8 may be supported by the drill string 20, for example by means of a bearing device (not shown) connected to the drill string, which supports the bending zone 14. In that case the upward force is suitably applied to the drill string 20, and then transmitted to the unexpanded liner section 8 through the bearing device. Furthermore, the weight of the unexpanded liner section 8 then can be transferred to the drill string and utilised to provide a thrust force to the drill bit 22.

Drilling fluid containing drill cuttings is discharged from the wellbore 1 via outlet conduit 90. Alternatively, drilling fluid may be circulated in reverse circulation mode wherein the drilling fluid is pumped into the wellbore via the conduit 90 and discharged from the wellbore via the drill string 20.

When it is required to retrieve the drill string 20 to surface, for example when the drill bit 22 is to be replaced or when drilling of the wellbore 1 is complete, the reamer section 26 can be collapsed to its radially retracted mode, wherein the radial diameter is smaller than the internal diameter of the unexpanded liner section 8. Subsequently, the drill string 20 can be retrieved through the unexpanded liner section 8 to surface.

With the wellbore system of the invention, it is achieved that the wellbore is progressively lined with the everted liner directly above the drill bit, during the drilling process. As a result, there is only a relatively short open-hole section 208 during the drilling process at all times. Short herein may indicate a length L1 (FIG. 1) of the open hole section of less than 1 km, for instance in the range of about 10 to 300 meter. Advantages of a short open hole section include limited possibility of influx into the wellbore, which will minimize the resulting pressure increase or pressure deviation and simplify and improve well control. The advantages of such short open-hole section will be most pronounced during drilling into a hydrocarbon fluid containing reservoir in the earth formation. In view thereof, for many applications it may be preferred if the process of liner eversion during drilling is applied only during drilling into the hydrocarbon fluid reservoir, or a formation section containing an anomaly, while other sections of the wellbore are lined or cased in a conventional manner. Alternatively, the process of liner eversion during drilling may be commenced at surface or at a selected downhole location, depending on circumstances.

In view of the short open-hole section during drilling, there is a significantly reduced risk that the wellbore fluid pressure gradient exceeds the fracture gradient of the rock formation, or that the wellbore fluid pressure gradient drops below the pore pressure gradient of the rock formation. Therefore, considerably longer intervals can be drilled at a single nominal diameter than in a conventional drilling practice wherein casings of stepwise decreasing diameter must be set at selected intervals.

Also, if the wellbore is drilled through a shale layer, such short open-hole section eliminates possible problems due to a heaving tendency of the shale.

After the wellbore has been drilled to the desired depth and the drill string has been removed from the wellbore, the length of unexpanded liner section that is still present in the wellbore can be left in the wellbore or it can be cut-off from the expanded liner section and retrieved to surface.

In case the length of unexpanded liner section is left in the wellbore, there are several options for completing the wellbore. These are, for example, as outlined below.

A) A fluid, for example brine, is pumped into the blind annulus 44 between the unexpanded and expanded liner sections so as to pressurise the annulus and increase the collapse resistance of the expanded liner section 10. Optionally one or more holes are provided in the bending zone 14 to allow the pumped fluid to be circulated.

B) Cement is pumped into the blind annulus 44 in order to create, after hardening of the cement, a solid body between the unexpanded liner section 8 and the expanded liner section 10. The cement may expand upon hardening.

C) The unexpanded liner section is radially expanded (i.e. clad) against the expanded liner section, for example by pumping, pushing or pulling an expander through the unexpanded liner section.

In the above examples, expansion of the liner is started at surface or at a downhole location. In case of an offshore wellbore wherein an offshore platform is positioned above the wellbore, it may be advantageous to start the expansion process at the offshore platform, at or above the water surface. Herein, the bending zone moves from the offshore platform to the seabed and subsequently into the wellbore. Thus, the resulting expanded tubular element not only forms a liner in the wellbore, but also a riser extending from the offshore platform to the seabed. The need for a separate riser is thereby obviated.

Furthermore, conduits such as electric wires or optical fibres for communication with downhole equipment can be extended in the annulus between the expanded and unexpanded sections. Such conduits can be attached to the outer surface of the tubular element before expansion thereof. Also, the expanded and unexpanded liner sections can be used as electricity conductors to transfer data and/or power downhole.

Since any length of unexpanded liner section that is still present in the wellbore after completion of the eversion process, will be subjected to less stringent loading conditions than the expanded liner section, such length of unexpanded liner section may have a smaller wall thickness, or may be of lower quality or steel grade, than the expanded liner section. For example, it may be made of pipe having a relatively low yield strength or relatively low collapse rating.

Instead of leaving a length of unexpanded liner section in the wellbore after the expansion process, the entire liner can be expanded with the method described above so that no unexpanded liner section remains in the wellbore. In such case, an elongate member, for example a pipe string, can be used to exert the necessary downward force to the unexpanded liner section during the last phase of the expansion process.

In order to reduce friction forces between the unexpanded and expanded liner sections during the expansion process, a friction reducing layer, such as a Teflon layer, may be applied between the unexpanded and expanded liner sections. For example, a friction reducing coating can be applied to the outer surface of the unexpanded section 8. The friction reducing layer reduces the force which is required to evert the liner and to push the unexpanded section into the wellbore. Thus said force is kept further below a so-called critical buckling load, which is the force at which the unexpanded liner will buckle or otherwise fail. Instead of, or in addition to, the friction reducing layer, centralizing pads and/or rollers can be applied in the blind annulus between the unexpanded and expanded sections to reduce the friction and the annular clearance.

Instead of expanding the expanded liner section against the wellbore wall (as described), the expanded liner section can be expanded against the inner surface of another tubular element, e.g. a casing or a liner, already present in the wellbore.

Although the embodiments of the invention have been described including a top drive, the present invention is likewise suitable for use with alternative drilling systems. The latter may include for instance a downhole motor instead of a top drive. Said downhole motor is a drilling tool comprised in the drill string directly above the bit. Activated by pressurized drilling fluid, it causes the bit to turn while the drill string does not rotate. Examples of the downhole motor include a positive-displacement motor and a downhole turbine motor. Also, any other drilling tool may be deployed to drill the borehole. Such drilling tool may include, for instance, an abrasive jetting device suspended at the end of a pipe string.

The present invention is likewise suitable for directional drilling, i.e. drilling wherein the drilling direction can be adjusted. For instance, a downhole motor may be used as a deflection tool in directional drilling, where it is made up between the bit and a bent sub, or the housing of the motor itself may be bent.

The present invention is not limited to the above-described embodiments thereof, wherein various modifications are conceivable within the scope of the appended claims. For instance, features of respective embodiments may be combined. 

1. A method for sealing an annulus enclosing a tubular element in a wellbore, wherein the tubular element is an expandable tubular element enclosing a tool string, wherein a downhole end portion of a wall of the expandable tubular element is bent radially outward and in axially reverse direction defining an expanded tubular section extending around an unexpanded tubular section, the method comprising the steps of: i) introducing a first drilling fluid in the wellbore; ii) drilling an open hole section of the wellbore using a drilling tool suspended at the end of the tool string; iii) pumping a second drilling fluid comprising particles into the wellbore; iv) filtering the particles out of the second drilling fluid near a downhole end of the tubular element; v) extending the tubular element into the open hole section of the wellbore by pushing the unexpanded section into the expanded tubular section, while directing at least part of the filtered particles to an annulus between the expanded tubular section and a wellbore wall.
 2. The method of claim 1, comprising the step of: vi) repeating steps i) to v).
 3. The method of claim 1, wherein the particles directed to the annulus fill said annulus with a layer of particles.
 4. The method of claim 1, wherein the step of filtering the particles comprises: moving a drill string provided with a filter member uphole, until said filter member engages a downhole end of the tubular element.
 5. The method of claim 4, wherein the step of introducing a first drilling fluid in the wellbore comprises: moving the drill string provided with the filter member downhole until the filter member is disengaged from the downhole end of the tubular element.
 6. The method of claim 1, wherein the step of filtering uses a filter means, comprising: a filtering section extending from a downhole end of the tubular section into the wellbore; and a flexible flap arranged at the downhole end of said filtering section to at least partially close an annulus between said filtering section and a drill string.
 7. The method of claim 6, wherein the flexible flap will at least partially open said annulus between the filtering section and the drill string when a pressure differential across said flap exceeds a threshold pressure.
 8. The method of claim 6, wherein said flap is comprised of one or more flap sections, together constituting a circular shape.
 9. The method of claim 1, wherein the particles are at least partially ferromagnetic, and wherein the step of filtering the particles comprises: arranging a magnet at the downhole end of the tubular member to attract at least a part of the particles.
 10. The method of claim 1, wherein at least some of the particles will swell when contacted with a predetermined fluid.
 11. The method of claim 10, wherein said predetermined fluid comprises water or hydrocarbons.
 12. The method of claim 1, comprising the steps of: arranging an impermeable pipe at the downhole end of the tubular element, having an outer diameter smaller than the wellbore and including a (moving) seal between said impermeable pipe and the downhole end of the tubular element, thus creating an annular space downstream of the downhole end of the tubular element; ensuring that the particles in the second drilling fluid have a particle density lower than a mud density of the second drilling fluid; wherein the step of filtering the particles out of the second drilling fluid includes accumulating the particles in the annular space due to their buoyancy.
 13. A system for sealing an annulus enclosing a tubular element in a wellbore, comprising: a tool string having a drilling tool suspended at a downhole end for drilling an open hole section of the wellbore; an expandable tubular element enclosing the tool string, wherein a downhole end portion of a wall of the expandable tubular element is bent radially outward and in axially reverse direction defining an expanded tubular section extending around an unexpanded tubular section; means for introducing a first drilling fluid in the wellbore; means for pumping a second drilling fluid comprising particles into the wellbore; a filter means arranged near the downhole end of the tubular element for filtering particles out of the second drilling fluid and for directing at least part of the filtered particles to an annulus between the expanded tubular section and a wellbore wall.
 14. The system of claim 13, wherein the filter means is selected from the group of: a filtering section extending from a downhole end of the tubular section into the wellbore and a flexible flap arranged at the downhole end of said filtering section to at least partially close an annulus between said filtering section and a drill string; and an impermeable pipe arranged at the downhole end of the tubular element, having an outer diameter smaller than the wellbore and including a (moving) seal between said impermeable pipe and the downhole end of the tubular element, thus creating an annular space downstream of the downhole end of the tubular element.
 15. The system of claim 13, for carrying out the method according to any of the previous claims. 